Multi-finger hand device

ABSTRACT

A multi-fingered hand device has damping members  17 - 19, 26, 27  mounted respectively on interjoint members  6 - 8, 21, 22  of respective finger mechanisms  1   a - 1   e  in a covering relation to outer peripheral surfaces thereof. Adjacent ones of the damping members are spaced from each other at joints  9 - 11, 23, 24  disposed therebetween. Resilient cover members  20   a - 20   e  are removably fitted over the respective finger mechanisms  1   a - 1   e . The resilient cover members  20   a - 20   e  are made of an elastomer such as rubber or the like. The multi-fingered hand device thus arranged is capable of gripping an object without causing damage to the object, is prevented from being smeared, and has increased maintainability.

TECHNICAL FIELD

The present invention relates to a multi-fingered hand device for robots.

BACKGROUND ART

There have heretofore been known multi-fingered hand devices for robots such as human-shaped robots, the multi-fingered hand devices having a plurality of finger mechanisms, which correspond to human fingers, extending from a palm assembly. Each of the finger mechanisms comprises a plurality of interjoint members, which correspond to phalanxes of human fingers, connected by joints. The finger mechanisms can be bent and extended when the interjoint members are turned about the joints.

The interjoint members of the finger mechanisms are usually made of a hard material such as metal or the like. Therefore, when an object is gripped by a plurality of finger mechanisms of a multi-fingered hand device, the object may be damaged by the finger mechanisms, and when the multi-fingered hand device is moved, a finger mechanism thereof may hit the object, possibly damaging the object.

The present invention has been made in view of the above background. It is an object of the present invention to provide a multi-fingered hand device which is capable of gripping an object without causing damage to the object, is prevented from being smeared, and has increased maintainability.

DISCLOSURE OF THE INVENTION

To achieve the above object, a multi-fingered hand device according to the present invention has a plurality of finger mechanisms extending from a palm assembly and each comprising a plurality of interjoint members successively connected by a plurality of finger joints, the multi-fingered hand device being characterized in that damping members are mounted on the respective interjoint members of the finger mechanisms in covering relation to outer peripheral surfaces of the interjoint members, and the damping members mounted respectively on adjacent ones of the interjoint members of the finger mechanisms are spaced from each other at the joint disposed between the adjacent ones of the interjoint members, and that extensible and contractible bottomed tubular resilient cover members are fitted respectively over said finger mechanisms including said damping members, said extensible and contractible bottomed tubular resilient cover members having closed ends at tip ends of said finger mechanisms, and when curved portions of the resilient cover members which are produced when the finger mechanisms are bent enter gaps between adjacent ones of the damping members, front walls of the damping members have a thickness for preventing the curved portions from being caught by the joints.

With the present invention, since the damping members are mounted on the respective interjoint members of the finger mechanisms in covering relation to outer peripheral surfaces of the interjoint members, shocks produced when the finger mechanisms hit an object are lessened. As the damping members on adjacent ones of the interjoint members of the finger mechanisms are spaced from each other at the joint disposed between the adjacent interjoint members, the finger mechanisms can be bent at the joints without fail.

Therefore, the multi-fingered hand device according to the present invention is capable of gripping an object without causing damage to the object.

The damping members may be made of urethane rubber of the like, for example.

If the finger mechanisms can be bent and extended by turning the interjoint members about the joints, then gaps between the damping members on adjacent ones of the interjoint members of the finger mechanisms should preferably be shaped as to be spread from the joint between the adjacent interjoint members toward the front surface of the finger mechanisms. With this structure, exposed portions of the joints of the finger mechanisms which are not covered with the damping members may be minimized without obstructing the bending action of the finger mechanisms at the joints.

If the damping members of the finger mechanisms are exposed, then when the multi-fingered hand device grips an object, the damping members of the finger mechanisms are brought into direct contact with the object, and hence tend to be smeared. The damping members are liable to be relatively expensive because they are generally required to have a certain thickness for a desired damping capability.

The resilient cover members fitted over the finger mechanisms according to the present invention prevent the damping members from being unduly smeared. Since the resilient cover members may be relatively thin, they may be relatively inexpensive. As the resilient cover members are extensible and contractible, the finger mechanisms can be bent without fail.

According to the present invention, furthermore, the front walls of the damping members have such a thickness for preventing the curved portions from being pressed against the joints. Therefore, the curved portions are prevented from being caught by the joints and hence damaged thereby, and hence the joints are prevented from suffering a malfunction which would otherwise occur if the curved portions were caught by the joints.

In the multi-fingered hand device according to the present invention which has the resilient cover members fitted over the finger mechanisms, if the finger mechanisms can be bent and extended by turning the interjoint members about the joints, then the resilient cover members of the respective finger mechanisms should preferably be arranged to cause front walls thereof to be curved at the joints of the finger mechanisms toward the joints when the finger mechanisms are bent.

With the above arrangement, when the finger mechanisms are bent, since the front walls of the resilient cover members of the finger mechanisms are curved so as to be concave inwardly at the joints of the finger mechanisms toward the joints, the front walls of the resilient cover members do not project outwardly (in a direction away from the joints) at the bent regions of the finger mechanisms. Consequently, when the multi-fingered hand device is operating, the resilient cover members do not interfere with the operation of the multi-fingered hand device, and are not caught by foreign matter.

In order to allow the front walls of the resilient cover members to be curved at the joints of the finger mechanisms toward the joints, recesses may be defined in the portions of the front walls at the joints, or the portions of the front walls at the joints may be made concave toward the joints in advance.

If the finger mechanisms can be bent and extended by turning the interjoint members about the joints, then the resilient cover members of the respective finger mechanisms should preferably be shaped complementarily to outer profiles of the finger mechanisms as they are extended such that a restoring force is produced to bias the finger mechanisms to an extended position when the finger mechanisms are bent.

Specifically, in the multi-fingered hand device, the finger mechanisms are generally biased to an extended position by biasing means such as springs, and are bent by drive power from an actuator such as an electric motor or the like. In the case where the resilient cover members of the respective finger mechanisms are shaped complementarily to outer profiles of the finger mechanisms as they are extended, when the finger mechanisms are bent, the finger mechanisms are biased to the extended position under a restoring force of the resilient cover members. As a result, biasing forces of the biasing means may be reduced.

Preferably, the resilient cover members of the respective finger mechanisms are thicker in at least a portion of back walls thereof behind the finger mechanisms than in front walls thereof.

With such an arrangement, when the finger mechanisms are bent, the restoring force of the resilient cover members that are bent together with the finger mechanism is increased, making it possible to further reduce the biasing forces of the biasing means such as springs or the like for biasing the finger mechanisms to the extended position.

According to the present invention, furthermore, it is preferable for the multi-fingered hand device to have a resilient cover member integrally joined to at least one of the resilient cover members of the respective finger mechanisms and removably mounted on the palm assembly in covering relation to a surface of the palm assembly.

With the above arrangement, the palm assembly together with the finger mechanism is covered with the resilient cover members to protect the hand device in its entirety against being smeared. Because the resilient cover member of the palm assembly is integrally joined to at least one of the resilient cover members of the respective finger mechanisms, the number of parts of the resilient cover members can be reduced.

According to the present invention, moreover, the resilient cover members of the respective finger mechanisms and the resilient cover member of the palm assembly should preferably be made of an elastomer. The resilient cover members can thus be manufactured relatively inexpensively.

According to the present invention, furthermore, the multi-fingered hand device is characterized in that the front walls of the damping members fitted over the finger mechanisms have recesses defined therein at the respective joints so as to be concave toward the joints, and the thickness of portions of the resilient cover members which are positioned at the recesses is smaller than the thickness of other portions of the resilient cover members.

According to the present invention, the multi-fingered hand device is characterized in that the recesses are spread toward the front walls of the resilient cover members.

With the above arrangement, when the finger mechanisms are bent, the front walls of the resilient covers are bent at the joints more reliably toward the joints. As a result, when the finger mechanisms are bent, the front walls of the resilient covers are prevented from partly projecting outwardly into interference with the operation of the hand device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a plan view of a multi-fingered hand device according to a first embodiment of the present invention, the view showing the multi-fingered hand device from its palm side;

FIG. 2 is a plan view showing essential parts of the multi-fingered hand device shown in FIG. 1;

FIG. 3 is a cross-sectional view taken along line I-I of FIG. 1;

FIG. 4 is a view illustrative of the manner in which a finger mechanism of the multi-fingered hand device shown in FIG. 1 operates;

FIG. 5 is a longitudinal cross-sectional view of a finger mechanism of a multi-fingered hand device according to a second embodiment of the present invention;

FIG. 6 is a longitudinal cross-sectional view of a finger mechanism of a multi-fingered hand device according to a third embodiment of the present invention;

FIG. 7 is a side elevational view of the finger mechanism shown in FIG. 6; and

FIG. 8 is a longitudinal cross-sectional view of a finger mechanism of a multi-fingered hand device according to a fourth embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

A first embodiment of the present invention will be described below with reference to FIGS. 1 through 4.

As shown in FIG. 1, a multi-fingered hand device 1 according to the present embodiment has a structure similar to human hands and comprises five finger mechanisms 1 a-1 e extending from a palm assembly 2. The finger mechanisms 1 a-1 e correspond respectively to the thumb, index finger, middle finger, ring finger, and little finger of a human hand.

The palm assembly 2 comprises an assembly of a hand palm forming member 3 and a hand back forming member 4 for forming the face of a hand palm (face side in FIG. 1) and the face of a hand back (reverse side in FIG. 1), respectively. A space defined between the hand palm forming member 3 and the hand back forming member 4 (an internal space in the palm assembly 3) serves as a region for accommodating therein drive mechanisms (not shown) for operating the finger mechanisms 1 a-1 e. The palm assembly 2 has a proximal end connected to an arm 5 of a robot.

Of the finger mechanisms 1 a-1 e, the finger mechanisms 1 b-1 e other than the finger mechanism 2 a which corresponds to the thumb extend substantially forward (upward in FIG. 1) from a distal end of the palm assembly 2 (an end of the palm assembly 2 which is opposite to the proximal end connected to the arm 5). These four finger mechanisms 1 b-1 e are identical in basic structure to each other. The structure of these four finger mechanisms 1 b-1 e will be described below.

FIGS. 2 through 4 are views showing the structure of the finger mechanism 1 c which corresponds to the middle finger. However, since the finger mechanisms 1 b-1 e are identical in basic structure to each other, but are different in partial size from each other, FIGS. 2 through 4 will be referred to as representing the structure of each of the finger mechanisms 1 b-1 e.

As shown in FIGS. 2 and 3, each of the finger mechanisms 1 b-1 e has three interjoint members 6-8 and three joints 9-11, and is of such a structure that the interjoint members 6-8 are successively joined by the joints 9-11 from a fixed member 12 that is fixed to the palm assembly 2. The fixed member 12 is fixed to the hand back forming member 4 within the palm assembly 2, as shown in FIG. 3, and has an end projecting through an opening 13 that is defined in the distal end of the palm assembly 2 in alignment with each of the finger mechanisms 1 b-1 e. The interjoint member 6 is connected to an end of the fixed member 12 by the joint 9.

In FIG. 1, the above components of only the finger mechanisms 1 c, 1 e are denoted by reference characters, and reference characters of the components of the finger mechanisms 1 b, 1 d are omitted from illustration.

As shown in FIGS. 2 and 3, the joints 9-11 have respective joint shafts 9 a, 10 a, 11 a as rotational shafts oriented in the same direction (substantially in the transverse direction of the palm assembly 2). The interjoint members 6-8 can be turned respectively about the axes of the joint shafts 9 a-11 a with respect to the fixed member 12, the interjoint member 6, and the interjoint member 7, respectively. The finger mechanisms 1 b-1 e can be bent and extended by turning the interjoint members 6-8 respectively about the joints 9-11.

In the multi-fingered hand device according to the present embodiment, the finger mechanisms 1 b-1 e have respective link mechanisms 16 each comprising a link arm 14 coupling the fixed member 12 and the interjoint member 7 to each other, and a link arm 15 coupling the interjoint member 6 and the interjoint member 8 to each other. The link arm 14 has an end rotatably supported on the fixed member 12 at a position which is closer to a back surface of the finger mechanisms 1 b-1 e (a lower surface in FIG. 3) than the joint shaft 9 a, and another end rotatably supported on the interjoint member 7 at a position which is closer to a front surface of the finger mechanisms 1 b-1 e (an upper surface in FIG. 3) than the joint shaft 10 a. The link arm 15 has an end rotatably supported on the interjoint member 6 at a position which is closer to the back surface of the finger mechanisms 1 b-1 e than the joint shaft 10 a, and another end rotatably supported on the interjoint member 8 at a position which is closer to the front surface of the finger mechanisms 1 b-1 e than the joint shaft 11 a.

Because of the link mechanism 16 constructed of the link arms 14, 15, when the interjoint member 6 is turned with respect to the fixed member 12, the interjoint member 7 is turned with respect to the interjoint member 6, and the interjoint member 8 is turned with respect to the interjoint member 7, in ganged relation to the interjoint member 7. Each of the finger mechanisms 1 b-1 e is thus bent and extended by turning the interjoint member 6 about the joint shaft 9 a with respect to the fixed member 12.

Although not shown as they do not represent essential part of the present invention, the interjoint member 6 of each of the finger mechanisms 1 b-1 e is biased to an extended position (shown in FIG. 3) by a spring (biasing means), with the result that the finger mechanisms 1 b-1 e are biased in their entirety to an extended position. When a drive mechanism comprising a wire, pulleys, an electric motor, etc. imparts rotational drive power to the interjoint member 6 against the bias of the spring, the finger mechanisms 1 b-1 e are bent, i.e., the interjoint members 6-8 are turned toward the palm side of the palm assembly 2, as shown in FIG. 4.

As shown in FIGS. 1 through 3, damping members 17-19 are mounted respectively on the interjoint members 6-8 of the finger mechanisms 1 b-1 e in covering relation to outer peripheral surfaces thereof. The damping members 17-19 are made of urethane rubber or the like, for example.

As shown in FIG. 3, of the damping members 1719, the damping member 17 mounted on the interjoint member 6 and the damping member 18 mounted on the interjoint member 7 next to the damping member 17 are spaced from each other at the joint 10 between the interjoint members 6, 7. Similarly, the damping member 18 mounted on the interjoint member 7 and the damping member 19 mounted on the interjoint member 8 are spaced from each other at the joint 11 between the interjoint members 7, 8. When the finger mechanisms 1 b-1 e are bent from an extended position, the damping members 17, 18 that are positioned next to each other are brought toward each other at a position which is closer to the front surface of the finger mechanisms 1 b-1 e than the joint shaft 10 a and are spaced away from each other at a position which is closer to the back surface of the finger mechanisms 1 b-1 e than the joint shaft 10 a. Accordingly, the gap between the damping members 17, 18 is shaped so as to spread toward the front surface of the finger mechanisms 1 b-1 e such that the damping members 17, 18 will not abut against and interfere with each other at the position closer to the front surface of the finger mechanisms 1 b-1 e than the joint shaft 10 a when the finger mechanisms 1 b-1 e are bent (see FIG. 3). The gap between the damping members 18, 19 is similarly shaped so as to spread toward the front surface of the finger mechanisms 1 b-1 e at the position closer to the front surface of the finger mechanisms 1 b-1 e than the joint shaft 11 a (see FIG. 3).

Resilient finger cover members 20 b-20 e are removably fitted respectively over the finger mechanisms 1 b-1 e in covering relation to the outer surfaces of the finger mechanisms 1 b-1 e including the damping members 17-19. The resilient finger cover members 20 b-20 e comprise thin tubular members having closed ends at the tip ends of the finger mechanisms 1 b-1 e. The resilient finger cover members 20 b-20 e are shaped complementarily to the outer profiles of the corresponding finger mechanisms 1 b-1 e as they are extended (the diameters of the resilient finger cover members 20 b-20 e are substantially equal to the outside diameters of the damping members 17-19 of the finger mechanisms 1 b-1 e). As shown in FIG. 3, the other end (open end) of each of the resilient finger cover members 20 b-20 e is inserted into the palm assembly 2 through the opening 13 therein. The resilient finger cover members 20 b-20 e are made of an elastomer such as rubber or the like and are extensible and contractible.

As shown in FIG. 1, the finger mechanism 1 a corresponding to the thumb extends obliquely forward from a side (rearward of the finger mechanism 1 b) of the palm assembly 2, and has two interjoint members 21, 22 and two joints 23, 24 as its major members. The finger mechanism 1 a is such a structure that the interjoint members 21, 22 are successively joined by the joints 23, 24 from the fixed member 25 that is fixed to the hand back forming member 4 within the palm assembly 2.

The joints 23, 24 have respective joint shafts 23 a, 24 a as rotational shafts. The interjoint members 21, 22 can be turned respectively about the axes of the joint shafts 23 a, 24 a with respect to the fixed member 25 and the interjoint member 21, respectively. The finger mechanism 1 a can be bent and extended by turning the interjoint members 21, 22 respectively about the joints 23, 24.

Although not shown, the interjoint members 21, 22 of the finger mechanism 1 a are biased to an extended position (shown in FIG. 1) by a spring (biasing means). When a drive mechanism comprising a wire, pulleys, an electric motor, etc. imparts rotational drive power to the interjoint member 22 against the bias of the spring, the finger mechanism 1 a is bent, i.e., the interjoint members 21, 22 are turned to bring the tip end of the finger mechanism 1 a toward the finger mechanisms 1 b-1 e when the finger mechanisms 1 b-1 e are bent.

As with the finger mechanisms 1 b-1 e, damping members 26, 27 are mounted respectively on the interjoint members 21, 22 of the finger mechanism 1 a in covering relation to outer peripheral surfaces thereof. The damping members 26, 27 are spaced from each other at the joint 24 therebetween. As with the finger mechanisms 1 b-1 e, the gap between the damping members 26, 27 is shaped so as to spread toward the front surface of the finger mechanism 1 a at the position closer to the front surface of the finger mechanism 1 a than the joint shaft 24 a.

Furthermore, as with the finger mechanisms 1 b-1 e, a resilient finger cover member 20 a in the form of a thin tubular member is removably fitted over the finger mechanism 1 a in covering relation to the outer surface of the finger mechanism 1 a including the damping members 27, 28, the resilient finger cover member 20 a having a closed end at the tip end of the finger mechanism 1 a. As with the resilient finger cover members 20 b-20 e for the finger mechanisms 1 b-1 e, the resilient finger cover member 20 a is made of an elastomer such as rubber or the like and can be stretched and contracted. The resilient finger cover member 20 a is shaped complementarily to the outer profile of the finger mechanism 1 a as it is extended (the diameter of the resilient finger cover member 20 a is substantially equal to the outside diameters of the damping members 22, 23 of the finger mechanism 1 a).

In the present embodiment, the finger cover members 20 a-20 e have a substantially uniform thickness.

A thin palm cover member 28 (see the imaginary lines in FIG. 1 and also see FIGS. 3 and 4) is removably mounted on the palm assembly 2 so as to cover the overall outer peripheral surface of the palm assembly 2 except for the regions where the finger mechanisms 1 a-1 e extend from the palm assembly 2. The palm cover member 28 is made of an elastomer as with the finger cover members 20 a-20 e.

With the multi-fingered hand device according to the present embodiment, since the damping members 1719, 26, 27 are mounted on the interjoint members 6-8, 21, 22 of the finger mechanisms 1 a-1 e, even if the finger mechanisms 1 a-1 e abut against an object when the multi-fingered hand device grips the object, no excessive shocks are applied to the object, thus avoiding undue damage to the object. Adjacent ones of the damping members 17-19, 26, 27 of the finger mechanisms 1 a-1 e are spaced from each other at the joint disposed therebetween. In particular, the gap between adjacent ones of the damping members 17-19, 26, 27 is shaped so as to spread toward the front surface of the finger mechanisms 1 a-1 e at the position closer to the front surface than the joint shaft of the joint. Therefore, when the finger mechanisms 1 a-1 e are bent, the damping members are prevented from abutting against each other, allowing the finger mechanisms 1 a-1 e to be bent without fail.

Inasmuch as the finger mechanisms 1 a-1 e including the damping members 17-19, 26, 27 are covered with the resilient finger cover members 20 a-20 e, the major members of the finger mechanisms 1 a-1 e and the damping members 17-19, 26, 27 are prevented from being smeared and worn. Particularly, the damping members 17-19, 26, 27, which are likely to be relatively thick and expensive for a desired damping capability, can have their service life increased by preventing themselves from smear and wear. A lubricant such as grease or the like is often applied to the joints 9-11, 23, 24 of the finger mechanisms 1 a-1 e. Since the finger mechanisms 1 a-1 e are covered with the resilient finger cover members 20 a-20 e, the lubricant is prevented from being attached to the surfaces of the multi-fingered hand device and scattered around.

The resilient finger cover members 20 a-20 e and the palm cover member 28 are smeared when the multi-fingered hand device is in operation. Since these cover members are thin and can be manufactured relatively inexpensively, they can be replaced at low expenses. The resilient cover members 20 a-20 e, 28 can be removed from the multi-fingered hand device and cleaned.

When the finger mechanisms 1 b-1 e are bent, the front surfaces of the resilient finger cover members 20 b-20 e on the finger mechanisms 1 b-1 e are basically curved toward the joints 9-11 at the respective joints 9-11, as shown in FIG. 4. At this time, the curved portions enter into the gaps at the joints 10, 11 on the front surface of the adjacent damping members (17, 18), (18, 19). In the present embodiment, the thickness of the damping members 17-19 on their front surface is of such a value that the curved portions of the resilient finger cover members 20 b-20 e are not pressed against the joints 9-11. Therefore, those curved portions are prevented from being caught and damaged by the joints 9-11, and hence the joints 9-11 are prevented from suffering a malfunction which would otherwise occur if the curved portions were caught by the joints 9-11. Though not illustrated, this holds true also for the resilient finger cover member 20 a of the finger mechanism 1 a corresponding to the thumb.

The resilient finger cover members 20 a-20 e of the finger mechanisms 1 a-1 e comprise resilient members shaped complementarily to the outer profiles of the corresponding finger mechanisms 1 a-1 e as they are extended. When the finger mechanisms 1 a-1 e are bent, the resilient finger cover members 20 a-20 e produce a restoring force for biasing the finger mechanisms 1 a-1 e to an extended position. Therefore, the springs (not shown) used to bias the finger mechanisms 1 a-1 e to an extended position may have their biasing forces reduced, and hence may be reduced in weight and size.

A second embodiment of the present invention will be described below with reference to FIG. 5. A multi-fingered hand device according to the second embodiment has a basic structure that is identical to the basic structure of the multi-fingered hand device according to the first embodiment, and differs from the multi-fingered hand device according to the first embodiment as to only partial structural details of resilient finger cover members and a resilient palm cover member. Therefore, those parts of the multi-fingered hand device according to the second embodiment which are identical to those of the multi-fingered hand device according to the first embodiment are denoted by identical reference characters, and will not be described in detail below.

FIG. 5, which is similar to FIG. 3, shows structural details of the finger mechanisms 1 b-1 e other than the finger mechanism 1 a which corresponds to the thumb. As shown in FIG. 5, each of the resilient finger cover members 20 b-20 e fitted over the respective finger mechanisms 1 b-1 e has an end, near the palm assembly 2, which is integrally joined to the resilient palm cover member 28. Although not shown, the resilient finger cover member 20 a fitted over the finger mechanism 1 a corresponding to the thumb similarly has an end, near the palm assembly 2, which is integrally joined to the resilient palm cover member 28. According to the present embodiment, therefore, the resilient finger cover members 20 a-20 e and the palm cover member 28 are integrally formed in the shape of a glove. Other structural details are exactly identical to those of the multi-fingered hand device according to the first embodiment.

The multi-fingered hand device according to the present embodiment operates in the same manner, and offers the same advantages, as the multi-fingered hand device according to the first embodiment. In addition, since the resilient finger cover members 20 a-20 e and the palm cover member 28 which are mounted on the multi-fingered hand device are unitary, the number of parts of those cover members is smaller than with the multi-fingered hand device according to the first embodiment, and the inventory control for those parts is facilitated.

In the present embodiment, all the resilient finger cover members 20 a-20 e are integrally formed with the palm cover member 28. However, only some (one through four) of the resilient finger cover members 20 a-20 e may be integrally formed with the palm cover member 28 in view of the ease with which those cover members are mounted on the multi-fingered hand device.

A third embodiment of the present invention will be described below with reference to FIGS. 6 and 7. A multi-fingered hand device according to the third embodiment has a basic structure that is identical to the basic structure of the multi-fingered hand device according to the first embodiment, and differs from the multi-fingered hand device according to the first embodiment as to only partial structural details of resilient finger cover members. Therefore, those parts of the multi-fingered hand device according to the third embodiment which are identical to those of the multi-fingered hand device according to the first embodiment are denoted by identical reference characters, and will not be described in detail below.

FIG. 6, which is similar to FIG. 3, shows structural details of the finger mechanisms 1 b-1 e other than the finger mechanism 1 a which corresponds to the thumb. As shown in FIG. 6, each of the resilient finger cover members 20 b-20 e fitted over the respective finger mechanisms 1 b-1 e has recesses 29 a, 29 b, 29 c defined in the front wall thereof at the respective joints 9-11 so as to be concave toward the joints 9-11. As shown in FIG. 7, these recesses 29 a, 29 b, 29 c extend from the front wall toward side walls of the resilient finger cover members 20 b-20 e. As shown in FIG. 6, the thickness of the portions of the resilient finger cover members 20 b-20 e which are positioned at the recesses 29 a, 29 b, 29 c is smaller than the thickness of the other portions of the resilient finger cover members 20 b-20 e. Though not illustrated, this holds true also for the resilient finger cover member 20 a fitted over the finger mechanism 1 a corresponding to the thumb. The resilient finger cover member 20 a has recesses defined therein at the joints 23, 24. Other structural details are exactly identical to those of the multi-fingered hand device according to the first embodiment.

The multi-fingered hand device according to the present embodiment operates in the same manner, and offers the same advantages, as the multi-fingered hand device according to the first embodiment, and is further advantageous as follows:

According to the first embodiment, since the front wall of each of the resilient finger cover members 20 a-20 e of the finger mechanisms 1 a-1 e is uniformly thick and smooth (see FIG. 3), when the finger mechanisms 1 a-1 e are bent, the front wall of the resilient finger cover members 20 a-20 e at the joints 9-11 may be curved so as to project outwardly depending on how much the resilient finger cover members 20 a-20 e are deteriorated.

According to the present embodiment, as shown in FIG. 7, the front wall of each of the resilient finger cover members 20 b-20 e of the finger mechanisms 1 b-1 e has the recesses 29 a-29 c positioned at the respective joints 9-11, and the thickness of the portions of the resilient finger cover members 20 b-20 e which are positioned at the recesses 29 a-29 c is smaller than the thickness of the other portions of the resilient finger cover members 20 b-20 e.

Therefore, when the finger mechanisms 1 b-1 e are bent, the front wall of each of the resilient finger cover members 20 b-20 e is curved more reliably toward the joints 9-11 at the respective joints 9-11. Specifically, when the finger mechanisms 1 b-1 e are bent to the shape shown in FIG. 4, the front wall of each of the resilient finger cover members 20 b-20 e is curved at the respective joints 9-11, and is curved more reliably in the shape shown in FIG. 4. This also holds true for the resilient finger cover member 20 a of the finger mechanism 1 a corresponding to the thumb.

As a result, with the multi-fingered hand device according to the present embodiment, when the finger mechanisms 1 a-1 e are bent, the front wall of each of the resilient finger cover members 20 a-20 e is prevented from partly projecting outwardly into interference with the operation of the hand device.

All or some of the resilient finger cover members 20 a-20 e according to the present embodiment may be integrally joined to the palm cover member 28 as with the multi-fingered hand device according to the second embodiment.

A fourth embodiment of the present invention will be described below with reference to FIG. 4. A multi-fingered hand device according to the fourth embodiment has a basic structure that is identical to the basic structure of the multi-fingered hand device according to the first embodiment, and differs from the multi-fingered hand device according to the first embodiment as to only partial structural details of resilient finger cover members. Therefore, those parts of the multi-fingered hand device according to the fourth embodiment which are identical to those of the multi-fingered hand device according to the first embodiment are denoted by identical reference characters, and will not be described in detail below.

FIG. 8, which is similar to FIG. 3, shows structural details of the finger mechanisms 1 b-1 e other than the finger mechanism 1 a which corresponds to the thumb. As shown in FIG. 8, each of the resilient finger cover members 20 b-20 e fitted over the respective finger mechanisms 1 b-1 e has a back wall thicker than a front wall thereof. Though not illustrated, this holds true also for the resilient finger cover member 20 a fitted over the finger mechanism 1 a corresponding to the thumb, i.e., resilient finger cover member 20 a has a back wall thicker than a front wall thereof. Other structural details are exactly identical to those of the multi-fingered hand device according to the first embodiment.

The multi-fingered hand device according to the present embodiment operates in the same manner, and offers the same advantages, as the multi-fingered hand device according to the first embodiment. In addition, because each of the resilient finger cover members 20 a-20 e fitted over the respective finger mechanisms 1 a-1 e is thicker in the back wall than in the front wall, when the finger mechanisms 1 a-1 e are bent, the resilient finger cover members 20 a-20 e undergo greater forces tending to restore them to an extended position than with the multi-fingered hand device according to the first embodiment. As a consequence, the springs (not shown) used to bias the finger mechanisms 1 a-1 e to an extended position may have their biasing forces reduced, and hence may be reduced in weight and size.

All or some of the resilient finger cover members 20 a-20 e according to the present embodiment may be integrally joined to the palm cover member 28 as with the multi-fingered hand device according to the second embodiment.

INDUSTRIAL APPLICABILITY

As described above, the multi-fingered hand device according to the present invention is useful as a multi-fingered hand device of a robot for performing various operations with a plurality of finger mechanisms as they are bent and extended. 

1. A multi-fingered hand device having a plurality of finger mechanisms extending from a palm assembly, each of said plurality of finger mechanisms comprising a plurality of interjoint members successively connected by a plurality of finger joints, said hand device comprising: damping members, said damping members being mounted on the respective interjoint members of the finger mechanisms in a covering relation to outer peripheral surfaces of the interjoint members, said damping members being mounted respectively on adjacent ones of the interjoint members of the finger mechanisms and being spaced from each other at the joint disposed between the adjacent ones of the interjoint members; extensible and contractible bottomed tubular resilient cover members, said extensible and contractible bottomed tubular resilient cover members being fitted, respectively, over said finger mechanisms including said damping members, said extensible and contractible bottomed tubular resilient cover members having closed ends at tip ends of said finger mechanisms; and wherein, when curved portions of the resilient cover members, which are produced when the finger mechanisms are bent, enter gaps between adjacent ones of the damping members, front walls of the damping members have a thickness for preventing the curved portions from being caught by the joints.
 2. (canceled)
 3. The multi-fingered hand device according to claim 1, wherein said finger mechanisms are adapted to be bent and extended when said interjoint members are turned about the joints, and wherein the resilient cover members of the respective finger mechanisms are arranged to cause front walls thereof to be curved at the joints of the finger mechanisms toward the joints when said finger mechanisms are bent.
 4. The multi-fingered hand device according to claim 1, wherein: said finger mechanisms are adapted to be bent and extended when said interjoint members are turned about the joints; and the resilient cover members of the respective finger mechanisms are shaped complementarily to outer profiles of the finger mechanisms as they are extended such that a restoring force is produced to bias the finger mechanisms to an extended position when the finger mechanisms are bent.
 5. The multi-fingered hand device according to claim 3, wherein the resilient cover members of the respective finger mechanisms are shaped complementarily to outer profiles of the finger mechanisms as they are extended such that a restoring force is produced to bias the finger mechanisms to an extended position when the finger mechanisms are bent.
 6. The multi-fingered hand device according to claim 4, wherein the resilient cover members of the respective finger mechanisms are thicker in at least a portion of back walls thereof behind the finger mechanisms than in front walls thereof.
 7. The multi-fingered hand device according to claim 5, wherein the resilient cover members of the respective finger mechanisms are thicker in at least a portion of back walls thereof behind the finger mechanisms than in front walls thereof.
 8. The multi-fingered hand device according to claim 1, wherein a resilient cover member is integrally joined to at least one of said resilient cover members of the respective finger mechanisms and removably mounted on said palm assembly in covering relation to a surface of the palm assembly.
 9. The multi-fingered hand device according to claim 1, wherein the resilient cover members of the respective finger mechanisms are made of an elastomer.
 10. The multi-fingered hand device according to claim 8, wherein the resilient cover members of the respective finger mechanisms and the resilient cover member of said palm assembly are made of an elastomer.
 11. The multi-fingered hand device according to claim 1, wherein the front walls of the damping members fitted over the finger mechanisms have recesses defined therein at the respective joints so as to be concave toward the joints, and the thickness of portions of the resilient cover members which are positioned at the recesses is smaller than the thickness of other portions of the resilient cover members.
 12. The multi-fingered hand device according to claim 11, wherein the recesses are spread toward the front walls of the resilient cover members.
 13. The multi-fingered hand device according to claim 3, wherein a resilient cover member is integrally joined to at least one of said resilient cover members of the respective finger mechanisms and removably mounted on said palm assembly in covering relation to a surface of the palm assembly.
 14. The multi-fingered hand device according to claim 4, wherein a resilient cover member is integrally joined to at least one of said resilient cover members of the respective finger mechanisms and removably mounted on said palm assembly in covering relation to a surface of the palm assembly.
 15. The multi-fingered hand device according to claim 5, wherein a resilient cover member is integrally joined to at least one of said resilient cover members of the respective finger mechanisms and removably mounted on said palm assembly in covering relation to a surface of the palm assembly.
 16. The multi-fingered hand device according to claim 6, wherein a resilient cover member is integrally joined to at least one of said resilient cover members of the respective finger mechanisms and removably mounted on said palm assembly in covering relation to a surface of the palm assembly.
 17. The multi-fingered hand device according to claim 7, wherein a resilient cover member is integrally joined to at least one of said resilient cover members of the respective finger mechanisms and removably mounted on said palm assembly in covering relation to a surface of the palm assembly.
 18. The multi-fingered hand device according to claim 3, wherein the resilient cover members of the respective finger mechanisms are made of an elastomer.
 19. The multi-fingered hand device according to claim 4, wherein the resilient cover members of the respective finger mechanisms are made of an elastomer.
 20. The multi-fingered hand device according to claim 5, wherein the resilient cover members of the respective finger mechanisms are made of an elastomer.
 21. The multi-fingered hand device according to claim 6, wherein the resilient cover members of the respective finger mechanisms are made of an elastomer.
 22. The multi-fingered hand device according to claim 7, wherein the resilient cover members of the respective finger mechanisms are made of an elastomer.
 23. The multi-fingered hand device according to claim 13, wherein the resilient cover members of the respective finger mechanisms and the resilient cover member of said palm assembly are made of an elastomer.
 24. The multi-fingered hand device according to claim 14, wherein the resilient cover members of the respective finger mechanisms and the resilient cover member of said palm assembly are made of an elastomer.
 25. The multi-fingered hand device according to claim 15, wherein the resilient cover members of the respective finger mechanisms and the resilient cover member of said palm assembly are made of an elastomer.
 26. The multi-fingered hand device according to claim 16, wherein the resilient cover members of the respective finger mechanisms and the resilient cover member of said palm assembly are made of an elastomer.
 27. The multi-fingered hand device according to claim 17, wherein the resilient cover members of the respective finger mechanisms and the resilient cover member of said palm assembly are made of an elastomer. 